Cylindrical battery

ABSTRACT

A cylindrical battery with an opening sealing body that seals an opening of a battery can. The opening sealing body includes a valve member, a metal plate disposed on an inner side of the battery with respect to the valve member, and an annular insulating member interposed between the valve member and the metal plate. The valve member and the metal plate are connected to each other at respective central portions. The valve member has an annular thin-walled portion which is deformable when an internal pressure of the battery increases, and a recessed portion is formed by the thin-walled portion on the insulating member opposing side of the valve member. The insulating member has a section P1 that covers a surface, on the valve member side, of the metal plate, and the section P1 has a rib to be housed in the recessed portion.

TECHNICAL FIELD

The present invention relates to a cylindrical battery.

BACKGROUND ART

A general cylindrical battery includes an electrode group, anelectrolyte, a battery can that houses the electrode group and theelectrolyte, and an opening sealing body that seals an opening of thebattery can. The opening sealing body includes a valve member, a metalplate disposed on the inner side of the battery with respect to thevalve member, and an annular insulating member interposed between thevalve member and the metal plate (see PTL 1). The valve member and themetal plate are connected to each other at respective central portions.The valve member has an annular thin-walled portion which is deformablewhen the battery internal pressure increases. The above-mentionedopening sealing body includes a current cut-off mechanism.

Hereinafter, the current cut-off mechanism will be described.

When the battery internal pressure increases due to an external shortcircuit or the like, the valve member receives the pressure, and thethin-walled portion of the valve member is deformed. Accordingly, thecentral portion of the valve member is pulled outwardly of the batteryalong with the central portion of the metal plate. When the batteryinternal pressure reaches a predetermined value, the surroundings of theconnection portion of the metal plate with the valve member is broken,or the connection portion between the metal plate and the valve memberis broken. In this manner, a current path between the valve member andthe metal plate is cut off.

CITATION LIST Patent Literature

PTL 1: WO 2016/157749

SUMMARY OF INVENTION

However, heat generated by an external short circuit or the like istransmitted to the opening sealing body, and the insulating member madeof resin is melted, and, for example, a portion on the outer side of thethin-walled portion of the valve member may come into contact with themetal plate to become conductive, and the current cut-off mechanism maynot operate effectively.

In consideration of what has been described above, an aspect of thepresent invention relates to a cylindrical battery including: anelectrode group; an electrolyte; a battery can that houses the electrodegroup and the electrolyte; and an opening sealing body that seals anopening of the battery can,

the opening sealing body including a valve member, a metal platedisposed on an inner side of the battery with respect to the valvemember, and an annular insulating member interposed between the valvemember and the metal plate, wherein the valve member and the metal plateare connected to each other at respective central portions, the valvemember has an annular thin-walled portion which is deformable when aninternal pressure of the battery increases, and a recessed portion isformed by the thin-walled portion on the insulating member opposing sideof the valve member, the insulating member has a section P1 that coversa surface, on the valve member side, of the metal plate, and the sectionP1 has a rib to be housed in the recessed portion.

According to the present invention, it is possible to provide a highlyreliable cylindrical battery in which the current cut-off mechanismoperates stably in case of misuse or the like.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a vertical cross-sectional view of a cylindrical batteryaccording to an embodiment of the present invention.

FIG. 2 is an enlarged cross-sectional view of an opening sealing body ofFIG. 1.

FIG. 3 is a vertical cross-sectional view of a composite body of FIG. 2.

FIG. 4 is a plan view of the composite body of FIG. 2.

FIG. 5 is a back view of the composite body of FIG. 2.

FIG. 6 is a vertical cross-sectional view illustrating a modification ofthe composite body of FIG. 2.

FIG. 7 is a vertical cross-sectional view illustrating anothermodification of the composite body of FIG. 2.

FIG. 8 is a vertical cross-sectional view of a composite body used in acylindrical battery according to another embodiment of the presentinvention.

DESCRIPTION OF EMBODIMENTS

A cylindrical battery according to an embodiment of the presentinvention includes an electrode group, an electrolyte, a battery canthat houses the electrode group and the electrolyte, and an openingsealing body that seals an opening of the battery can. The openingsealing body includes a valve member, a metal plate disposed on an innerside of the battery with respect to the valve member, and an annularinsulating member interposed between the valve member and the metalplate. The valve member and the metal plate are connected to each otherat respective central portions. The valve member has an annularthin-walled portion which is deformable when an internal pressure of thebattery increases, and a recessed portion is formed by the thin-walledportion on the insulating member opposing side of the valve member. Theinsulating member has a section P1 that covers a surface, on the valvemember side, of the metal plate, and the section P1 has a rib to behoused in the recessed portion.

Since the section P1 has a rib, the amount of resin (thermal capacity)of the insulating member is increased. Thus, it is possible to reducethe risk of melting of the insulating member due to the heat generatedby an external short circuit or the like, and contact between a portionon the outer side of the thin-walled portion of the valve member and themetal plate is controlled. In addition, since the rib is housed in therecessed portion formed by the thin-walled portion, the insulationdistance between the valve member (particularly, the portion on theouter side of the thin-walled portion) and the metal plate is furtherlargely ensured. Thus, it is possible to obtain a highly reliablecylindrical battery in which the current cut-off mechanism operatesstably at the time of an external short circuit, for example. The shape,disposition, and form of the rib may be determined as appropriateaccording to the shape and position of the recessed portion.

The metal plate and the insulating member preferably have respectiveholes which communicate with each other. In this case, when the batteryinternal pressure increases, the valve member can reliably receive thepressure through the holes provided in the metal plate and theinsulating member, and the current cut-off mechanism operates stably.The holes of the metal plate are provided in the area other than thecentral portion (the connection portion with the valve member) of themetal plate.

It is preferable that multiple (for example, two to 12, preferably fourto eight) holes of the metal plate and the insulating member be providedalong the circumferential direction of the metal plate and theinsulating member. In this case, when the battery internal pressureincreases, the thin-walled portion of the valve member is likely toreceive the battery internal pressure uniformly in the circumferentialdirection.

The insulating member includes a resin which can ensure the insulatingproperty, and does not affect to the battery characteristics. Theinsulating member may further include a filler such as glass fiber.Resins used as the insulating member include, for example, polypropylene(PP), polybutylene terephthalate (PBT), polyphenylene sulfide (PPS),polyamide (PA), polytetrafluoroethylene (PTFE),tetrafluoroethylene-perfluoroalkyl vinyl ether copolymer (PFA). Theresins used as the insulating member are preferably PP and PBT among allfrom the viewpoint of cost advantage, superior heat resistance, and easeof integration with the metal plate by an insert molding.

The insulating member is produced using a general molding technique. Theinsulating member is preferably produced integrally with the metal plateby an insert molding among all. The insulating member and the metalplate can be bonded by an insert molding without using an adhesiveagent. The insulating member integrated with the metal plate can beproduced, for example, by loading a metal plate into a predeterminedmold, and injecting a molten resin into the mold. By using an insertmolding technique, the insulating member can be obtained integrally withthe metal plate, and not only the surface, on the valve member side, ofthe metal plate, but also the area from the circumferential end face orthe lateral sides of holes of the metal plate to the surface, on thebattery inner side (the opposite side to the valve member), of the metalplate can be easily covered by the insulating member. In other words,subsequent to the section P1, the later-described sections P2 to P6 canbe easily provided. Thus, the metal plate can be further protected bythe insulating member. Thus, coming off of the metal plate from theinsulating member due to deformation of the opening sealing body at thetime of battery crush by pressure, and an internal short circuit(contact between the metal plate and the electrode group or the batterycan) caused by the coming off of the metal plate are controlled. Also,because of the integration of the insulating member with the metalplate, the thicknesses of the metal plate and the insulating member canbe reduced, and accordingly the size of the electrode group can beincreased and a higher capacity thereof can be aimed.

When the insulating member is separately produced, then is stacked onand fixed to the metal plate, in order to reduce the positional gapbetween the holes of the insulating member and the metal plate, the holediameter of the insulating member needs to be larger than the holediameter of the metal plate.

In contrast, when the insulating member is produced integrally with themetal plate by an insert molding, the process of stacking and fixing theinsulating member on and to the metal plate can be omitted, and thedifference between the hole diameters of the insulating member and themetal plate may be reduced, and the hole diameter of the insulatingmember may be smaller than the hole diameter of the metal plate, ascompared with when the insulating member is stacked on and fixed to themetal plate. In other words, when viewed in the thickness direction ofthe metal plate, the portion exposed from the insulating member in thesurroundings of the holes of the metal plate can be reduced oreliminated.

Also, by an insert molding, part of the holes (openings) of the metalplate can be covered by the insulating member (the section P1). Thelateral sides of the holes of the metal plate can be covered by theinsulating member (the section P2).

First Embodiment

Hereinafter a non-aqueous electrolyte secondary battery as an example ofa cylindrical battery according to an embodiment of the presentinvention will be described with reference to FIGS. 1 to 5. FIG. 1 is avertical cross-sectional view of a non-aqueous electrolyte secondarybattery. FIG. 2 is a vertical cross-sectional view of an opening sealingbody of FIG. 1. FIG. 3 is a vertical cross-sectional view of a compositebody of FIG. 2. FIG. 4 is a plan view of the composite body of FIG. 3.FIG. 5 is a back view of the composite body of FIG. 3.

A non-aqueous electrolyte secondary battery (hereinafter a battery) 10includes an electrode group 18, an electrolyte (not illustrated), and abottomed cylindrical battery can 22 that houses these. An openingsealing body 11 is caulking-fixed to the opening of the battery can 22via a gasket 21. Thus, the battery inside is hermetically sealed.

The opening sealing body 11 includes a valve member 12, a metal plate13, and an annular insulating member 14 interposed between the valvemember 12 and the metal plate 13. The valve member 12 and the metalplate 13 are connected to each other at respective central portions. Theinsulating member 14 provides insulation between the valve member 12 andthe metal plate 13 in the area other than the connection portion betweenthe valve member 12 and the metal plate 13. As illustrated in FIGS. 3 to5, the insulating member 14 is integrated with the metal plate 13 by aninsert molding. In other words, the insulating member 14 and the metalplate 13 form a composite body 19.

For example, aluminum or aluminum alloy is used for the valve member 12and the metal plate 13. The valve member 12 and the metal plate 13 areproduced by machine pressing a plate material such as aluminum into apredetermined shape. The central portion of the valve member 12 and thecentral portion of the metal plate 13 are connected using, for example,a welding technique such as laser welding.

The valve member 12 is circular when viewed in the thickness directionof the metal plate 13, and has an annular thin-walled portion 12 a whichis deformable when the internal pressure of the battery 10 increases.The thin-walled portion 12 a has an inclined area A1 where the thicknessof the thin-walled portion 12 a is continuously decreased in the radialdirection from the center to the circumferential end face, the inclinedarea A1 being on the surface, on the inner side of the battery 10, ofthe valve member 12. Thus, the end, on the circumferential end side, ofthe valve member 12 in the inclined area A1 serves as a starting pointof deformation of the valve member 12 when the internal pressure of thebattery 10 increases. The rate of change of the thickness of thethin-walled portion 12 a (the inclined area) may be constant or may bechanged from the center to the circumferential end face. When the valvemember 12 is viewed in the thickness direction of the metal plate 13,the length (width) of the annular thin-walled portion 12 a (the inclinedarea A1) in the radial direction equals to, for example, 10 to 80%,preferably 10 to 40% of the radius of the valve member 12.

In the present embodiment, the thickness of the thin-walled portion iscontinuously decreased from the center to the circumferential end faceof the valve member. However, the thickness of the thin-walled portionmay be continuously increased from the center to the circumferential endface of the valve member. In this case, the end, on the central side, ofthe valve member serves as a starting point of deformation of the valvemember when the battery internal pressure increases. However, in orderto deform the valve member more stably, it is preferable that thethickness of the thin-walled portion be continuously decreased from thecenter to the circumferential end face of the valve member. Also,although the entire thin-walled portion is the inclined area in thepresent embodiment, part of the thin-walled portion may be the inclinedarea.

A recessed portion 12 b is formed by the thin-walled portion 12 a on theinsulating member 14 opposing side of the valve member 12. Theinsulating member 14 has the section P1 that covers the surface, on thevalve member 12 side, of the metal plate 13. The section P1 has anannular rib 14 a to be housed in the recessed portion 12 b. Because ofthe inclined area of the thin-walled portion 12 a, the recessed portion12 b has an inclined face at its bottom, and the rib 14 a has aninclined face corresponding to the bottom of the recessed portion 12 b.By providing the rib 14 a, contact between the valve member and metalplate due to melting of the insulating member (the section P1) at thetime of an external short circuit or the like is controlled, and theinsulation distance between a portion on the outer side of thethin-walled portion 12 a of the valve member and the metal plate isfurther largely ensured. The ratio of the length (width) of the annularrib 14 a in the radial direction to the length (width) of the annularthin-walled portion 12 a (the recessed portion 12 b) in the radialdirection as viewed in the thickness direction of the metal plate 13 is,for example, 10% or greater, and preferably 30% or greater.

The metal plate 13 and the insulating member 14 respectively have holes13 b and holes 14 b which communicate with each other. When thepositional gap between corresponding hole 14 b and hole 13 b needs to beprevented, the hole diameter of the hole 14 b is set to be slightlylarger than the hole diameter of the hole 13 b as illustrated in FIGS. 3and 4. In contrast, in the case of an insert molding, positional gapbetween the holes does not occur, thus the hole diameter of the hole 14b may be substantially equal to the hole diameter of the hole 13 b, orthe hole diameter of the hole 14 b may be smaller than the hole diameterof the hole 13 b unlike FIGS. 3 and 4. In the present embodiment, eightholes 13 b and eight holes 14 b are provided along the circumferentialdirection. However, the number of holes is not limited to this.

The metal plate 13 is circular when viewed in the axial direction of thebattery 10. As illustrated in FIGS. 2 to 5, the metal plate 13 has athin-walled portion 13 a at its central portion (the connection portionwith the valve member). The surface, on the outer side of the battery10, of the metal plate may have an annular groove (not illustrated)along the circumferential edge of the thin-walled portion 13 a. In thiscase, when the battery internal pressure reaches a predetermined value,the groove is stably broken. Also, the breaking strength of the grooveis easily adjusted.

The section P1 covers the area other than the central portion (thethin-walled portion 13 a) of the surface, on the valve member 12 side,of the metal plate 13, and has multiple holes 14 b.

As illustrated in FIG. 2, the valve member 12 preferably has aprotrusion portion 12 c at the central portion of the surface on theinner side of the battery. The protrusion portion 12 c makes it easy toconnect the central portion of the valve member 12 and the centralportion of the metal plate 13 as well as to dispose the insulatingmember 14 between the area other than the central portion of the valvemember 12 and the area other than the central portion of the metal plate13. The protrusion portion 12 c is disposed in a hollow portion 14 c ofthe insulating member 14.

As illustrated in FIG. 2, it is preferable that the valve member 12further have an annular projection portion 12 d on the circumferentialedge of the surface on the battery inner side. The projection portion 12d makes it easy to fix the composite body 19 to the valve member 12.

An annular groove (not illustrated) may be formed in the valve member12. In this case, the valve member 12 can operate further stably as anexplosion-proof valve. The groove of the valve member 12 may be providedin the thin-walled portion 12 a. The cross-sectional shape of the grooveof the valve member 12 preferably has a V-character shape or aU-character shape.

As illustrated in FIGS. 3 and 4, it is preferable that the section P1have an area A2 which coves part of the holes 13 b (openings) of themetal plate 13, and at least part of the rib 14 a be provided in thearea A2. In this case, the insulation distance between the valve member(particularly, the portion on the outer side of the thin-walled portion12 a) and the metal plate is further largely ensured. When viewed in thethickness direction of the metal plate 13, the proportion of the holes13 b (openings) of the metal plate 13 covered by the area A2 is, forexample, 10 to 80%, and preferably 30 to 60%.

As illustrated in FIGS. 2 and 3, it is preferable that the insulatingmember 14 further have a section P2 that is provided subsequent to thesection P1 and covers the lateral sides of the holes 13 b of the metalplate 13. In this case, the insulation distance between the valve member(particularly, the portion on the outer side of the thin-walled portion12 a) and the metal plate is further largely ensured.

It is sufficient that the lateral side of at least one of the multipleholes of the metal plate be covered by the section P2. As illustrated inFIGS. 3 and 4, it is preferable that the lateral sides of the multipleholes 13 b be each covered by the section P2. It is sufficient that thesection P2 cover at least part (for example, a portion closer to theouter side portion of the thin-walled portion 12 a) of the lateral sidesof the holes of the metal plate. The proportion of the lateral sides,covered by the section P2, of the holes of the metal plate is preferably20 to 90%, and more preferably 40 to 80%.

As illustrated in FIGS. 2 and 3, it is preferable that the insulatingmember 14 further have a section P4 that is provided subsequent to thesection P1 and covers the circumferential end face of the metal plate13. In this case, the insulation distance between the valve member(particularly, the portion on the outer side of the thin-walled portion12 a) and the metal plate is further largely ensured. When the valvemember has the projection portion 12 d as illustrated in FIG. 2, contactbetween the projection portion 12 d and the metal plate is controlled.

As illustrated in FIGS. 2, 3, and 5, it is preferable that theinsulating member 14 further have an annular section P6 that is providedsubsequent to the section P2 and the section P4, and covers the surface,on the inner side of the battery 10, of the metal plate 13. In otherwords, the later-described section P3 and section P5 may be connected.In this case, the metal plate is stably fixed to the insulating member,thus coming off of the metal plate from the insulating member due todeformation of the opening sealing body at the time of battery crush bypressure, and an internal short circuit (contact between the metal plateand the electrode group or the battery can) caused by the coming off ofthe metal plate are controlled.

As illustrated in FIGS. 3 and 5, the surface, on the inner side of thebattery 10, of the metal plate 13 may have an area which is not coveredby the section P6 and in which the metal plate 13 is exposed, the areabeing other than the thin-walled portion 13 a. On the surface, on theinner side of the battery 10, of the metal plate 13, it is preferablenot to dispose the section P6 and the later-described sections P3, P5 inat least the area outside the thin-walled portion 13 a and inside theholes 13 b. The area is utilized for connection to the later-describedpositive electrode lead 15 a.

Instead of the composite body 19 (the insulating member 14) illustratedin FIG. 3, a composite body 39 (an insulating member 34) illustrated inFIG. 6 may be used. The composite body 39 has the same configuration asthat of the composite body 19 except that instead of the section P6, asection P3 is provided, which is provided subsequent to the section P2and covers the surface, on the inner side of the battery 10, of themetal plate 13. The section P3 is provided subsequent to the sections P1and P2, and the metal plate is thereby stably fixed to the insulatingmember. Thus, coming off of the metal plate from the insulating memberdue to deformation of the opening sealing body at the time of batterycrush by pressure, and an internal short circuit (contact between themetal plate and the electrode group or the battery can) caused by thecoming off of the metal plate are controlled. The composite body 39 mayfurther have the later-described section P5.

It is sufficient that the section P3 cover at least part of the surface,on the inner side of the battery 10, of the metal plate 13, and it ispreferable that the section P3 be provided in an annular shape from thesection P2 on the surface, on the inner side of the battery 10, of themetal plate 13 toward the circumferential end face. For example, alength L1 of the section P3 illustrated in FIG. 6 is preferably greaterthan or equal to 0.2 mm, and more preferably greater than or equal to0.3 mm. The length L1 illustrated in FIG. 6 is, for example, 3% orgreater, and preferably 4% or greater of the radius of the metal plate13.

Also, instead of the composite body 19 (the insulating member 14)illustrated in FIG. 3, a composite body 49 (an insulating member 44)illustrated in FIG. 7 may be used. The composite body 49 has the sameconfiguration as that of the composite body 19 except that instead ofthe section P6, a section P5 is provided, which is provided subsequentto the section P4 and covers the surface, on the inner side of thebattery 10, of the metal plate 13. The section P5 is provided subsequentto the sections P1 and P4, and the metal plate is thereby stably fixedto the insulating member. Thus, coming off of the metal plate from theinsulating member due to deformation of the opening sealing body at thetime of battery crush by pressure, and an internal short circuit(contact between the metal plate and the electrode group or the batterycan) caused by the coming off of the metal plate are controlled. Thecomposite body 49 may further have the section P3.

It is sufficient that the section P5 cover at least part of the surface,on the inner side of the battery 10, of the metal plate 13, and it ispreferable that the section P5 be provided to cover the area greaterthan or equal to 0.2 mm from the circumferential end face of thesurface, on the inner side of the battery 10, of the metal plate 13toward the center. In other words, it is preferable that the length L2(the radial length of the area where the surface, on the inner side ofthe battery 10, of the metal plate 13 is covered by the section P5)illustrated in FIG. 7 be greater than or equal to 0.2 mm. In this case,coming off of the metal plate from the insulating member due todeformation of the opening sealing body at the time of battery crush bypressure, and an internal short circuit (contact between the metal plateand the electrode group or the battery can) caused by the coming off ofthe metal plate are further controlled. The length L2 illustrated inFIG. 7 is more preferably greater than or equal to 0.3 mm. When theinsulating member 14 is viewed in the thickness direction of the metalplate 13, the length L2 is, for example, 3% or greater, and preferably4% or greater of the radius of the metal plate 13. The section P5 may beannular, and may be provided at intervals along the circumferentialdirection of the metal plate.

In the present embodiment, the annular rib 14 a which covers part of theholes 13 b is provided. However, the disposition and the shape of therib are not limited to this. For example, the rib may be disposedbetween adjacent holes 13 b of the metal plate 13 at intervals along thecircumferential direction.

Second Embodiment

Hereinafter, a cylindrical battery according to another embodiment ofthe present invention will be described with reference to FIG. 8. FIG. 8is a vertical cross-sectional view of a composite body used in thecylindrical battery according to another embodiment of the presentinvention. The battery according to the present embodiment has the sameconfiguration as that of the battery 10 illustrated in FIG. 1 exceptthat instead of the composite body 19 (the insulating member 14)illustrated in FIG. 3, a composite body 59 (an insulating member 54)illustrated in FIG. 8 is used. The composite body 59 includes the metalplate 13 and an insulating member 54. The insulating member 54 has thesection P1 having the rib 14 a, and the section P4. The composite body59 has the same configuration as that of the composite body 19 with thesections P2, P6 of the insulating member 14 removed.

Since the insulating member 54 has the rib 14 a at the section P1,contact between the valve member and metal plate due to melting of theinsulating member (the section P1) at the time of an external shortcircuit or the like is controlled, and the insulation distance betweenthe valve member (particularly, the portion on the outer side of thethin-walled portion 12 a) and the metal plate is further largelyensured.

As illustrated in FIG. 8, it is preferable that the section P1 of theinsulating member 54 have an area A2 which coves part of the holes 13 b(openings), and at least part of the rib 14 a be provided in the areaA2. In this case, the insulation distance between the valve member(particularly, the portion on the outer side of the thin-walled portion12 a) and the metal plate is further largely ensured.

Hereinafter, the current cut-off mechanism will be described.

When the battery internal pressure increases due to an external shortcircuit or the like, the valve member 12 receives the pressure throughthe holes 13 b of the metal plate 13 and the holes 14 b of theinsulating member 14, and the thin-walled portion 12 a of the valvemember 12 is deformed. Accordingly, the central portion of the valvemember 12 is pulled outwardly of the battery along with the centralportion of the metal plate 13. When the battery internal pressurereaches a predetermined value, an annular groove (not illustrated)provided in the surroundings of the connection portion of the metalplate 13 with the valve member 12 is broken, and a current path betweenthe valve member 12 and the metal plate 13 is cut off.

In the case where the metal plate 13 has no groove, a configuration maybe adopted in which when the battery internal pressure reaches apredetermined value, the connection portion (welded portion) between themetal plate 13 and the valve member 12 is broken (a configuration inwhich the central portion of the metal plate 13 is detached from thecentral portion of the valve member 12). The breaking strength of agroove of the metal plate is easier to be adjusted than the breakingstrength of the connection portion (welded portion), thus the metalplate 13 preferably has a groove in the surroundings of the connectionportion with the valve member 12. The cross-sectional shape of thegroove of the metal plate 13 preferably has a V-character shape or aU-character shape.

A positive electrode lead 15 a drawn from a positive electrode plate 15is connected to the metal plate 13. Thus, the valve member 12 functionsas an external terminal of the positive electrode. A negative electrodelead 16 a drawn from a negative electrode plate 16 is connected to thebottom internal surface of the battery can 22.

For example, iron, iron alloy, stainless steel, aluminum, and aluminumalloy are used as the material for the battery can 22. An annual groove22 a is formed in the vicinity of the opening end of the battery can 22.A first insulating plate 23 is disposed between one end face of theelectrode group 18 and the annual groove 22 a. A second insulating plate24 is disposed between the other end face of the electrode group 18 andthe bottom of the battery can 22.

The electrode group 18 is formed by winding the positive electrode plate15, the negative electrode plate 16, and a separator 17 interposedtherebetween.

The positive electrode plate 15 includes a foil positive electrodecurrent collector, and a positive electrode active material layer formedon its surface. For example, aluminum, aluminum alloy, stainless steel,titanium, and titanium alloy are used as the material for the positiveelectrode current collector. A lithium transition metal composite oxideis preferably used as the positive electrode active material. Forexample, a composite oxide is used, which includes at least one typeselected from a group and lithium, the group consisting of cobalt,manganese, nickel, chromium, iron, and vanadium.

The negative electrode plate 16 includes a foil negative electrodecurrent collector, and a negative electrode active material layer formedon its surface. For example, copper, copper alloy, nickel, nickel alloy,and stainless steel are used as the material for the negative electrodecurrent collector. A carbon material which can reversibly occlude anddischarge lithium ions, for example, natural graphite, artificialgraphite, hard carbon, soft carbon, tin oxide, and oxide silicon may beused as the negative electrode active material.

For example, a microporous membrane composed of polyolefin may be usedas the separator 17. As polyolefin, polyethylene, polypropylene, andethylene-propylene copolymer may be exemplified.

The electrolyte includes a non-aqueous solvent, and lithium saltdissolved in the non-aqueous solvent. As the non-aqueous solvent, acyclic carbonate such as an ethylene carbonate, a propylene carbonate,and a butylene carbonate, a chain carbonate such as a dimethylcarbonate, a diethyl carbonate, and an ethyl methyl carbonate, acarboxylic acid ester, and a chain ether are used. As the lithium salt,LiPF₆, LiBF₄, LiClO₄, and the like are used.

INDUSTRIAL APPLICABILITY

The cylindrical battery according to the present invention is useful asa small-sized electronic device such as a notebook personal computer, apower tool for an electric tool and an electric power-assisted bicycle,and a driving power source for an electric automobile.

REFERENCE SIGNS LIST

-   -   10 NON-AQUEOUS ELECTROLYTE SECONDARY BATTERY    -   11 OPENING SEALING BODY    -   12 VALVE MEMBER 12 a THIN-WALLED PORTION    -   12 b RECESSED PORTION    -   12 c PROTRUSION PORTION    -   12 d PROJECTION PORTION    -   13 METAL PLATE    -   13 a THIN-WALLED PORTION    -   13 b HOLE    -   14, 34, 44, 54 INSULATING MEMBER    -   14 a RIB 14 b HOLE    -   14 c HOLLOW PORTION    -   15 POSITIVE ELECTRODE PLATE    -   15 a POSITIVE ELECTRODE LEAD    -   16 NEGATIVE ELECTRODE PLATE    -   16 a NEGATIVE ELECTRODE LEAD    -   17 SEPARATOR    -   18 ELECTRODE GROUP    -   19, 39, 49, 59 COMPOSITE BODY    -   21 GASKET    -   22 BATTERY CAN    -   22 a GROOVE    -   23 FIRST INSULATING PLATE    -   24 SECOND INSULATING PLATE

1. A cylindrical battery comprising: an electrode group; an electrolyte;a battery can that houses the electrode group and the electrolyte; andan opening sealing body that seals an opening of the battery can, theopening sealing body including a valve member, a metal plate disposed onan inner side of the battery with respect to the valve member, and anannular insulating member interposed between the valve member and themetal plate, wherein the valve member and the metal plate are connectedto each other at respective central portions, the valve member has anannular thin-walled portion which is deformable when an internalpressure of the battery increases, and a recessed portion is formed bythe thin-walled portion on the insulating member opposing side of thevalve member, the insulating member has a section P1 that covers asurface, on the valve member side, of the metal plate, and the sectionP1 has a rib to be housed in the recessed portion.
 2. The cylindricalbattery according to claim 1, wherein the metal plate and the insulatingmember have respective holes which communicate with each other.
 3. Thecylindrical battery according to claim 2, wherein the section P1 has anarea which covers part of the holes of the metal plate, and at leastpart of the rib is provided in the area.
 4. The cylindrical batteryaccording to claim 2, wherein the insulating member further has asection P2 that is provided subsequent to the section P1 and covers alateral side of the holes of the metal plate.
 5. The cylindrical batteryaccording to claim 4, wherein the insulating member further has asection P3 that is provided subsequent to the section P2 and covers thesurface, on the inner side of the battery, of the metal plate.
 6. Thecylindrical battery according to claim 1, wherein the insulating memberfurther has a section P4 that is provided subsequent to the section P1and covers a circumferential end face of the metal plate.
 7. Thecylindrical battery according to claim 6, wherein the insulating memberfurther has a section P5 that is provided subsequent to the section P4and covers a surface, on an inner side of the battery, of the metalplate.
 8. The cylindrical battery according to claim 7, wherein thesection P5 is provided to cover an area greater than or equal to 0.2 mmfrom the circumferential end face of the surface, on the inner side ofthe battery, of the metal plate toward a center.
 9. The cylindricalbattery according to claim 1, wherein the insulating member isintegrated with the metal plate by adhesive bonding.